JP2009231924A - Frame data transfer system and frame data transfer apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent deterioration of transmission quality, and immediately perform highly reliable frame data transfer in a network system with a plurality of switches connected to a plurality of transfer networks forming a network. <P>SOLUTION: An apparatus is provided with: the switches connected to the transfer networks forming the network; broadcasting ports 10 by which the respective switches connect with the plurality of the transfer networks; terminal ports connecting with terminals; a frame data transfer unit 40 which controls transfer destinations of the frame data; an address learning table unit 41 which stores corresponding to address information 42 storing addresses showing transmission sources of the frame data, port information 43 receiving the frame data, and transfer flag information 44 showing either one of transferring the frame data to all broadcasting ports 10, or transferring the frame data to broadcast ports 10 shown by the receiving port information 43; and a timer unit 45 which changes the transfer flag information 44 in a predetermined interval. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention comprises a plurality of layer 2 switching devices connected to the plurality of transfer networks, having a plurality of transfer networks, a frame data transfer unit, and a plurality of broadcast ports connected to the plurality of transfer networks. The address indicating the data transmission source and the port information from which the frame data is received are associated with each other and stored in the address learning table unit, and the frame data is transferred to the plurality of transfer networks based on the information stored in the address learning table unit. The present invention relates to a highly reliable layer 2 frame data transfer system.

  As a layer 2 frame data transfer system (hereinafter referred to as “frame data transfer system”) using a conventional IEEE 802.3 layer 2 switch (hereinafter referred to as “switch”), for example, a frame data transfer system disclosed in Patent Document 1 is: By configuring multiple transfer networks in a redundant manner, even if a failure occurs in one transfer network, it is possible to transfer frame data using another transfer network, thus realizing highly reliable transfer of frame data. ing.

JP 2006-324792 A

When one switch connected to the transfer network described above (hereinafter referred to as “A switch”) does not receive frame data for a certain period of time, the information stored in the address learning table portion of the A switch is aging (switch When the frame data is not received for a certain period of time, the address learning table of the A switch is automatically deleted by the operation of automatically erasing information stored in the address learning table unit in order to effectively use the area of the address learning table unit. The information stored in the section (source address of frame data not received: Source Address; hereinafter referred to as “SA”) is deleted.

  Thereafter, when the switch A receives frame data addressed to a terminal connected to another switch (hereinafter referred to as “B switch”) from the terminal connected to the A switch, address learning (frame data) of the frame data is performed. In the switch that receives the address information, the address learning table section (to be described later) does not perform “floating” (address learning) because “SA” and “reception port information” that received the frame data are stored in pairs. The frame data including the destination address (hereinafter referred to as “DA”) is transferred to the terminal indicated by the DA, and the frame data is sent to all ports. Forward.

  In addition, when the A switch, the B switch, and the C switch are connected to the above-described transfer network (hereinafter referred to as “0-system transfer network”, “1-system transfer network”), each switch receives the same frame data. Highly reliable frame data is transferred by transferring to both the 0-system transfer network and the 1-system transfer network. Here, when the terminal connected to the A switch and the terminal connected to the B switch continue to transmit and receive frame data, address learning is performed in each of the 0-system transfer network and the 1-system transfer network. The frame data is not transferred to the C switch.

  However, for example, when a failure has occurred in a part of the 0-system transfer network, the failure location is a location between the A switch and the B switch and a location other than between the A switch and the C switch. When aging occurs in the 0-system transfer network in which the error occurred, the frame data transmitted to the transfer network in which the A switch has failed is transmitted to the C switch by flooding. Since the C switch that received the frame data is aged in the same manner, the C switch is also forwarded to the terminal to which the C switch is connected by flooding.

  On the other hand, for example, even when a failure occurs in the 0-system transfer network, if frame data is transmitted to the 1-system transfer network, the 1-system transfer network transmits frame data to the B switch without causing flooding. Is possible.

  In the above-described 0-system transfer network, bandwidth is consumed by unnecessary frame data in flooding, but transfer is resumed at the troubled part of the 0-system transfer network that has been recovered along with the failure recovery.

  That is, when a failure occurs in the transfer network, if a certain period of time elapses and aging occurs, unnecessary flooding occurs continuously, so the communication network bandwidth of the transfer network where the failure occurred and the transfer There is a problem that the bandwidth of the communication line of the switch connected to the network and the bandwidth of the communication line of the terminal connected to the switch are consumed for the unnecessary flooding, and transmission quality deteriorates.

  The present invention has been made in view of the above, and an object of the present invention is to provide a frame data transfer system capable of preventing deterioration in transmission quality and immediately transferring reliable frame data. To do.

  In order to solve the above-described problems and achieve the object, the present invention provides a network system including a plurality of switches connected to a plurality of transfer networks forming a network, wherein each switch includes the plurality of transfer networks. Broadcast ports that connect to each other, terminal ports that connect terminals, frame data transfer units that control the transfer destination of frame data, address information that stores addresses indicating the transmission source of frame data, and ports that receive frame data Information and an address for storing transfer flag information indicating that either frame data is transferred to all broadcast ports or frame data is transferred to the broadcast port indicated in the reception port information in association with each other A learning table unit, and a timer unit that changes the transfer flag information at predetermined intervals. The features.

  According to the present invention, the operation of the frame data transfer unit is controlled by the operation of the timer unit, and the frame data is transferred to all broadcast ports or broadcast ports indicated in the reception port information. There are effects that the deterioration of the transmission quality of the frame data can be prevented and that the frame data can be immediately and reliably transferred.

  Embodiments of a frame data transfer system according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram showing a configuration of a frame data transfer system 300 to which the switch according to the first embodiment of the present invention is applied. In FIG. 1, a frame data transfer system 300 includes, as main components, a 0-system transfer network 100, a 1-system transfer network 200, and a plurality of switches (hereinafter referred to as “A switch 1”, “B switch 2”). And “C switch 3”) and terminal devices (hereinafter referred to as “terminals”) connected to the switches. The number of transfer networks and switches is not limited to that shown in FIG. 1, and each switch can transmit and receive frame data to and from terminals not shown.

  Each switch can be connected to any place in the transfer network. As an example, an A switch 1 is connected to one end of the transfer network, a B switch 2 is connected to the other end, and a C switch 3 is connected therebetween. It shall be.

  Each switch connects a port connecting the 0-system transfer network 100 (hereinafter referred to as “0-system broadcast port”), a port connecting the 1-system transfer network 200 (hereinafter referred to as “1-system broadcast port”), and a terminal. A port (hereinafter referred to as “terminal port”), a frame data transfer unit 40 that transfers received frame data to each port, and a timer unit 45 are provided. Further, it is assumed that an A terminal 4 is connected to the A switch 1, a B terminal 5 is connected to the B switch 2, and a C terminal 6 is connected to the C switch 3. The number and type of ports provided in each switch are not limited to this.

  The frame data transfer unit 40 includes an address learning table unit 41. The address learning table unit 41 includes address information 42 that stores “SA” of received frame data, reception port information 43 that stores information indicating a port (terminal port or broadcast port) that has received frame data, and transfer. It consists of flag information 44.

  In the transfer flag information 44, the frame data is transferred to all broadcast ports (hereinafter referred to as “1”), or the frame data is transferred to the broadcast port stored in the reception port information 43 (hereinafter referred to as “transfer data”). Or “0”). The transfer flag information 44 includes a numerical value “1” or “0” as an example, but is not limited thereto.

  The timer unit 45 is for changing the transfer flag information 44 from “0” to “1” at predetermined intervals. That is, the frame data transfer unit 40 can transfer frame data to all broadcast ports at a predetermined interval by the operation of the timer unit 45. The predetermined interval described above is not limited to an equal interval. In FIG. 1, the C switch 3 omits the address learning table unit 41 and the timer unit 45, but is assumed to include these as in the case of the A switch 1.

  The frame data transmitted from each terminal stores “SA” and “DA” as described above. For example, when the address of the A terminal 4 is “XX” and the address of the B terminal 5 is “YY”, when the A terminal 4 transmits frame data to the B terminal 5, the SA “XX” is included in the frame data. DA “YY” is stored, and when frame data is transmitted from the B terminal 5 to the A terminal 4, SA “YY” and DA “XX” are stored.

  Each switch performs the address learning described above when frame data is newly received. Thereafter, when the frame data is received again, each switch determines whether or not “SA” (for example, “XX”) of the received frame data matches the address stored in the address learning table unit 41. If they do not match, that is, when frame data including an address whose address has not been learned is received, “XX” and the port (terminal port or broadcast port) that received the frame data are stored as a set, but they match. In this case, since address learning has been completed, they are not stored. At the same time, each switch determines whether or not “DA” (for example, “YY”) of the received frame data matches the address stored in the address learning table unit 41. The frame data received from all the ports is transmitted by the operation, and if they match, the frame data is transmitted only from the received ports stored in pairs with the addresses.

  2 to 5 are diagrams showing the state of the address learning table unit 41 of the A switch 1 when no failure has occurred in the transfer network of the frame data transfer system 300. FIG. Hereinafter, a frame data transfer operation in the frame data transfer system 300 will be described. In FIG. 1, the 0-system transfer network 100 is marked with a “failure occurrence” symbol, which is used for explanation when a failure occurs in a part of the system, which will be described later. Here, the description will be made assuming that the 0-system transfer network is in a normal state. The same applies to symbols in the drawings for explaining other embodiments described later.

  FIG. 2 is a diagram illustrating a state when the A terminal 4 transmits frame data including SA “XX” and DA “YY” to the B terminal 5 when the A switch 1 is not performing address learning. is there. The A switch 1 performs address learning, and stores “XX” in the address information 42, “A terminal port 12” in the reception port information 43, and “0” in the transfer flag information 44. The frame data is simultaneously transferred to the A0 system broadcast port 10 and the A1 system broadcast port 11 by flooding (hereinafter referred to as “broadcast transfer”), via the 0 system transfer network 100 and the 1 system transfer network 200, B is transmitted to the switch 2.

  When receiving the frame data transmitted from the A switch 1, the B switch 2 selects only one frame data and transfers it to the B terminal port 22. Note that address learning is also performed in the B switch 2, but the description is omitted because it is the same as that in the A switch. Hereinafter, the same applies to the description of the operation of the B switch 2.

  Next, when the B terminal 5 transmits frame data including SA “YY” and DA “XX” to the A terminal 4, the frame data is transferred to the 0-system transfer network 100 by the frame data transfer unit 40 of the B switch 2. And broadcast transmission to the 1-system transmission network 200.

  FIG. 3 shows that the A switch 1 that has received the frame data transmitted from the B switch 2 adds “YY” to the address information 42 and “A0 series broadcast” to the reception port information 43 in addition to the address learning table unit 41 described above. It is a figure which shows the state which stored the set of "0" in the port 10, A1 system broadcast port 11 ", and the transfer flag information 44. FIG. Since the broadcast port is a port that transmits and receives the same frame data, a plurality of broadcast ports are stored in the reception port information 43 as described above. Since the reception port information 43 corresponding to DA “XX” is “A terminal port 12”, the frame data is transferred to the A terminal port 12 according to the contents of the address learning table unit 41.

  Finally, when the A terminal 4 transmits frame data including SA “XX” and DA “YY” to the B terminal 5, the A switch 1 confirms the address information 42. As a result, the address learning table unit 41 includes a pair of address “YY”, receiving port “A0 system broadcast port 10, A1 system broadcast port 12” and transfer flag “0” corresponding to DA “YY”. It is confirmed that it is stored.

  Here, since the transfer flag information 44 corresponding to the address “YY” of the address information 42 is “0”, the frame data is A0 of the reception port information 43 corresponding to the address “YY” according to the contents of the address learning table unit 41. The data is transferred to both the system broadcast port 10 and the A1 system broadcast port 11, and is transmitted to the B switch 2 by broadcast.

  FIG. 4 is a diagram showing a state after the transfer flag information 44 is changed from “0” to “1” at a predetermined interval. When the transfer flag information 44 is “1”, the frame data received from the A terminal 4 includes all broadcast ports of the A0 system broadcast port 10 and the A1 system broadcast port 11 regardless of the contents of the reception port information 43. And broadcasted to the B switch 2.

  FIG. 5 is a diagram showing a state after the transfer flag information 44 is changed from “1” to “0” after one frame data is transferred. When the transfer flag information 44 is “0”, the frame data received from the A terminal 4 is transferred to both the A0 system broadcast port 10 and the A1 system broadcast port 11 according to the contents of the reception port information 43, and the B switch 2 is broadcast.

  As described above, when there is no failure in the transfer network, frame data can be transferred to both the 0-system transfer network and the 1-system transfer network even if the transfer flag information 44 changes. High frame data transfer is possible. The above-described embodiment can be applied to switches other than layer 2, and the same applies to the following embodiments.

  Next, an operation when a failure occurs in a part of the transfer network (for example, the 0-system transfer network) in the frame data transfer system 300 will be described.

  In FIG. 1, as described above, in the middle of the 0-system transfer network 100 connecting the B switch 2 and the C switch 3, a place where a failure has occurred is marked with “failure occurrence”. In this case, the frame data transmitted from the A1 system broadcast port 11 of the A switch 1 reaches the B switch 2 via the 1 system transfer network 200. When this failure occurs and a certain time elapses, the information of the B terminal 5 is deleted from the address learning table 41 by aging in the 0-system transfer network 100. As a result, flooding occurs in the 0-system transfer network 100, so that the frame data addressed to the B terminal 5 transmitted from the A0-system broadcast port 10 passes through the 0-system transfer network 100 and does not require transfer. Will reach the state.

  6 to 10 are diagrams illustrating the state of the address learning table unit 41 of the A switch 1 in the frame data transfer system 300. FIG.

  FIG. 6 is a diagram illustrating a state when the A terminal 4 transmits frame data including SA “XX” and DA “YY” to the B terminal 5 when the A switch 1 is not performing address learning. is there. The A switch 1 performs address learning, and stores “XX” in the address information 42, “A terminal port 12” in the reception port information 43, and “0” in the transfer flag information 44. The frame data is transferred to the A0 system broadcast port 10 and the A1 system broadcast port 11 by flooding. However, since a failure has occurred in the 0 system transfer network 100, the B1 is transmitted via the 1 system transfer network 200. It is transmitted to the system broadcast port 21.

  When the B switch 2 receives the frame data transmitted from the A switch 1, the B switch 2 performs address learning in the same manner as the A switch 1 and transfers the frame data to the B terminal port 22.

  Next, when the B terminal 5 transmits frame data including SA “YY” and DA “XX” to the A terminal 4, the frame data is simultaneously transferred to the B0 system broadcast port 20 and the B1 system broadcast port 21. However, since a failure has occurred in the 0-system transfer network 100, it is transmitted to the A1 system broadcast port 11 via the 1-system transfer network 200.

  FIG. 7 shows that the A switch 1 that has received the frame data, in addition to the address learning table unit 41 described above, has “YY” in the address information 42 and “A1 system broadcast port 11” in the reception port information 43 and transfer flag information. FIG. 44 is a diagram illustrating a state in which a group of “0” is stored in 44. Since the reception port information 43 corresponding to DA “XX” is “A terminal port 12”, the frame data is transferred to the A terminal port 12 according to the contents of the address learning table unit 41.

  Finally, when the A terminal 4 transmits frame data including SA “XX” and DA “YY” to the B terminal 5, the A switch 1 confirms the address information 42. As a result, the address learning table unit 41 stores a set of the address “XX”, the reception port “A terminal port 12”, and the transfer flag “0” corresponding to the SA “XX”, and the address “XX”. Is confirmed to have been learned. It is confirmed that a set of address “YY”, receiving port “A1 system broadcast port 11” and transfer flag “0” corresponding to DA “YY” is stored.

  Here, since the transfer flag information 44 corresponding to the address “YY” of the address information 42 is “0”, the frame data is A1 of the reception port information 43 corresponding to the address “YY” according to the contents of the address learning table unit 41. The data is transferred only to the system broadcast port 11 and transmitted to the B switch 2 via the system 1 transfer network 200. Since no frame data is transferred to the 0-system transfer network 100, no frame data is transferred to the C switch 3 by flooding in the 0-system transfer network 100.

  FIG. 8 is a diagram showing a state after the transfer flag information 44 is changed from “0” to “1” at a predetermined interval. At this time, the transfer flag information 44 of the set whose reception port information 43 is a broadcast port is changed. When the transfer flag information 44 is “1”, the frame data received from the A terminal 4 is transferred not only to the A1 system broadcast port 11 but also to the A0 system broadcast port 10. That is, the transfer operation to all broadcast ports is performed.

  FIG. 9 is a diagram showing a state after transfer flag information 44 is changed from “1” to “0” after one frame data is transferred. When the transfer flag information 44 is “0”, the frame data received from the A terminal 4 is transferred only to the A1 system broadcast port 11. That is, when the transfer flag information 44 changes from “1” to “0”, the frame data transfer unit 40 returns to the transfer operation of transferring the frame data to the broadcast port stored in the reception port information 43.

  Since the B switch 2 operates in the same manner as described above, when the failure of the transfer network is recovered, the frame data from the 0-system transfer network 100 recovered from the failure is received, and then the B switch 2 is addressed to the A switch 1 The frame data to be transmitted to is transmitted to both the 0-system transfer network 100 and the 1-system transfer network 200.

  FIG. 10 shows that the A switch 1 that has received the frame data transmitted from the B switch 2 adds “YY” to the address information 42 and “A0 system broadcast to the reception port information 43 in addition to the address learning table unit 41 described above. It is a figure which shows the state which stored the set of "0" in the port 10, A1 system broadcast port 11 ", and the transfer flag information 44. FIG. As a result, the storage state of the address learning table unit 41 is the same as that in FIG. 3 showing the state of the address learning table unit 41 when no failure has occurred in the transfer network.

  As described above, according to the frame data transfer system 300 of the first embodiment, when a failure occurs in the transfer network, it is possible to prevent unnecessary flooding from occurring continuously, and when the transfer network is restored. Broadcast transfer can be started on the transfer network restored at a predetermined interval. As a result, when a failure occurs in the transfer network, it is possible to prevent deterioration in the transmission quality of frame data, and when the transfer network is restored, reliable transfer of frame data can be performed immediately. it can. The transfer flag information 44 is described as changing from “1” to “0” when one frame data is transferred. However, when a plurality of frame data is transferred, the transfer flag information 44 is changed from “1” to “0”. May be.

Embodiment 2. FIG.
FIG. 11 is a diagram showing a configuration of a frame data transfer system 400 to which the switch according to the second exemplary embodiment of the present invention is applied. The difference from the switch of the first embodiment is that a broadcast learning table unit 46 is added.

  When one or both of the A0 system broadcast port 10 and the A1 system broadcast port 11 receives frame data from other switches, the broadcast learning table unit 46 broadcasts frame data for each broadcast port. It is a part for storing information indicating the switch device that has performed the transfer. For example, when no failure has occurred in the transfer network, when the B switch 2 transmits frame data to the A switch 1, the frame data is transmitted to both the A0 system broadcast port 10 and the A1 system broadcast port 11. Therefore, the information “B switch 2” indicating the switch device that performed the broadcast transfer is stored in both the A0 system broadcast port information 47 and the A1 system broadcast port information 48. That is, the quantity of information stored in the A0 system broadcast port information 47 and the A1 system broadcast port information 48 is equal and there is no significant difference (one or both of the 0 system transport network 100 and the 1 system transport network 200 has a fault. It can be said that this is not happening). On the other hand, when a failure occurs in a part of the 0-system transfer network 100 as described above, when the B switch 2 transmits frame data to the A switch 1, the frame data is received only by the A1 system broadcast port 11. . Therefore, only the A1 system broadcast port information 48 stores information “B switch 2” indicating the switch device that has performed the broadcast transfer. That is, the quantity of information stored in the A0 system broadcast port information 47 and the A1 system broadcast port information 48 is different and has a significant difference (one or both of the 0 system transport network 100 and the 1 system transport network 200 has a fault. Is not happening).

  The switch according to the second embodiment controls the operation of the frame data transfer unit 40 by determining whether or not the quantity of information stored in the broadcast learning table unit 46 is the same.

  Hereinafter, an operation when a failure occurs in the transfer network in the frame data transfer system 400 will be described.

  12 to 16 are diagrams showing the state of the address learning table unit 41 of the A switch 1 in the frame data transfer system 400 described above.

  FIG. 12 is a diagram illustrating a state when the A terminal 4 transmits frame data including SA “XX” and DA “YY” to the B terminal 5 when the A switch 1 is not performing address learning. is there. The A switch 1 performs address learning, and stores “XX” in the address information 42, “A terminal port 12” in the reception port information 43, and “0” in the transfer flag information 44. The frame data is transferred to the A0 system broadcast port 10 and the A1 system broadcast port 11 by flooding. However, since a failure has occurred in the 0 system transfer network 100, the B1 is transmitted via the 1 system transfer network 200. Received at the system broadcast port 21.

  When the B switch 2 receives the frame data transmitted from the A switch 1, the B switch 2 performs address learning in the same manner as the A switch 1 and transfers the frame data to the B terminal port 22.

  Next, when the B terminal 5 transmits frame data including SA “YY” and DA “XX” to the A terminal 4, the frame data is simultaneously transferred to the B0 system broadcast port 20 and the B1 system broadcast port 21. However, since a failure has occurred in the 0-system transfer network 100, it is received by the A1 system broadcast port 11 via the 1-system transfer network 200.

  FIG. 13 shows that the A switch 1 that has received the frame data transmitted from the B switch 2 adds “YY” to the address information 42 and “A1 system broadcast to the reception port information 43 in addition to the address learning table unit 41 described above. FIG. 10 is a diagram showing a state in which a set of “0” is stored in “Port 11” and transfer flag information 44, and “B switch 2” is stored in A1 system broadcast port information 48; Since the reception port information 43 corresponding to DA “XX” is “A terminal port 12”, the frame data is transferred to the A terminal port 12 according to the contents of the address learning table unit 41.

  Finally, when the A terminal 4 transmits frame data including SA “XX” and DA “YY” to the B terminal 5, the A switch 1 confirms the address information 42. As a result, the address learning table unit 41 stores a set of the address “XX”, the reception port “A terminal port 12”, and the transfer flag “0” corresponding to the SA “XX”, and the address “XX”. Is confirmed to have been learned. It is confirmed that a set of address “YY”, receiving port “A1 system broadcast port 11” and transfer flag “0” corresponding to DA “YY” is stored.

  Here, the first embodiment recognizes the transfer flag information 44 and performs the transfer operation. However, as described above, the second embodiment recognizes the state of the broadcast learning table unit 46 and performs the transfer operation. Is to do. Although no information is stored in the A0 system broadcast port information 47, the A1 system broadcast port information 48 stores information “B switch 2”. Therefore, the frame data transfer unit 40 recognizes that a lot of information is stored in the A1 system broadcast port information 48, and transfers the frame data only to the A1 system broadcast port 11. Since no frame data is transferred to the 0-system transfer network 100, no frame data is transferred to the C switch 3 by flooding in the 0-system transfer network 100.

  FIG. 14 is a diagram showing a state after the transfer flag information 44 is changed from “0” to “1” at a predetermined interval. At this time, the transfer flag information 44 of the set whose reception port information 43 is a broadcast port is changed. When the transfer flag information 44 is “1”, the frame data received from the A terminal 4 is transferred not only to the A1 system broadcast port 11 but also to the A0 system broadcast port 10. That is, the transfer operation to all broadcast ports is performed.

  FIG. 15 is a diagram showing a state after the transfer flag information 44 is changed from “1” to “0” after one frame data is transferred. When the transfer flag information 44 is “0”, the frame data received from the A terminal 4 is transferred only to the A1 system broadcast port 11. That is, when the transfer flag information 44 changes from “1” to “0”, the frame data transfer unit 40 returns to the transfer operation of transferring the frame data to the broadcast port stored in the reception port information 43.

  Since the B switch 2 operates in the same manner as described above, when the failure of the transfer network is recovered, the frame data from the 0-system transfer network 100 recovered from the failure is received, and then the B switch 2 is addressed to the A switch 1 The frame data to be transmitted to is transmitted to both the 0-system transfer network 100 and the 1-system transfer network 200.

  FIG. 16 is a diagram illustrating a state of the address learning table unit 41 when the frame data transmitted from the B switch 2 is received. In addition to the information in the address learning table unit 41, the A switch 1 stores a set of SA “YY”, receiving port “A0 system broadcast port 10, A1 system broadcast port 11”, and transfer flag “0”. To do. Further, since “B switch 2” is stored in the A0 system broadcast port information 47, the number of information stored in the A0 system broadcast port information 47 and the A1 system broadcast port information 48 is equal.

  After that, when the A switch 1 receives the frame data from the A terminal 4, the frame data transfer unit 40 recognizes that the number of information of the A0 system broadcast port information 47 and the A1 system broadcast port information 48 is the same. The frame data is transferred to the A1 system broadcast port 11 and the A0 system broadcast port 10.

  As described above, in the switch of the second embodiment, the frame data transfer unit 40 recognizes whether or not the number of pieces of information in the broadcast learning table unit 46 is the same, thereby transferring the same as the switch of the first embodiment. It enables operation. In other words, when a failure occurs in the transfer network, it is possible to prevent unnecessary flooding from occurring continuously. When the transfer network is restored, broadcast transmission is started on the restored transfer network at a predetermined interval. can do. As a result, when a failure occurs in the transfer network, it is possible to prevent deterioration in the transmission quality of frame data, and when the transfer network is restored, reliable transfer of frame data can be performed immediately. it can. The description of the operation when no failure has occurred in the transfer network is omitted.

Embodiment 3 FIG.
FIG. 17 is a diagram showing a configuration of a frame data transfer system 500 to which the switch according to the third embodiment of the present invention is applied.

  The difference from the switch of the first embodiment is that each switch has transfer amount information 49 for storing the size (amount) of frame data transferred to the broadcast port. When the amount of data stored in the transfer amount information 49 is less than a predetermined value (hereinafter referred to as “X byte”), the frame data is transferred only to the port stored in the reception port information 43, and the predetermined value In the above case (hereinafter referred to as “Y byte”), it is possible to transfer frame data to all broadcast ports. As described above, the switch according to the third embodiment controls the operation of the frame data transfer unit 40 by determining whether the amount of information stored in the transfer amount information 49 is less than a predetermined value. is there.

  Hereinafter, an operation in the case where a failure occurs in the transfer network in the frame data transfer system 500 will be described.

  18 to 22 are diagrams showing the state of the address learning table unit 41 of the A switch 1 in the frame data transfer system 500 described above.

  FIG. 18 is a diagram showing a state when the A terminal 4 transmits frame data including SA “XX” and DA “YY” to the B terminal 5 when the A switch 1 is not performing address learning. is there. The A switch 1 performs address learning, and stores “XX” in the address information 42, “A terminal port 12” in the reception port information 43, and “X byte” in the transfer amount information 49. The frame data is transferred to the A0 system broadcast port 10 and the A1 system broadcast port 11 by flooding. However, since a failure has occurred in the 0 system transfer network 100, the B1 is transmitted via the 1 system transfer network 200. Received at the system broadcast port 21.

  When the B switch 2 receives the frame data broadcasted from the A switch 1, the B switch 2 performs address learning in the same manner as the A switch 1 and transfers the frame data to the B terminal port 22.

  Next, when the B terminal 5 transmits frame data including SA “YY” and DA “XX” to the A terminal 4, the frame data is simultaneously transferred to the B0 system broadcast port 20 and the B1 system broadcast port 21. However, since a failure has occurred in the 0-system transfer network 100, it is received by the A1 system broadcast port 11 via the 1-system transfer network 200.

  FIG. 19 shows that the A switch 1 that has received the frame data transmitted from the B switch 2 adds “YY” to the address information 42 and “A1 system broadcast to the reception port information 43 in addition to the address learning table unit 41 described above. It is a figure which shows the state which stored the group of "X byte" in the port 11 "and the transfer amount information 49. FIG. Since the reception port information 43 corresponding to DA “XX” is “A terminal port 12”, the frame data is transferred to the A terminal port 12 according to the contents of the address learning table unit 41.

  Finally, when the A terminal 4 transmits frame data including SA “XX” and DA “YY” to the B terminal 5, the A switch 1 confirms the address information 42. As a result, the address learning table unit 41 stores a set of the address “XX”, the reception port “A terminal port 12”, and the transfer flag “0” corresponding to the SA “XX”, and the address “XX”. Is confirmed to have been learned. It is confirmed that a set of address “YY”, receiving port “A1 system broadcast port 11”, and transfer amount information “X byte” corresponding to DA “YY” is stored.

  Here, the amount of frame data transferred to the A1 system broadcast port 11 is “X byte” as described above. Therefore, the frame data received from the A terminal 4 is transferred only to the A1 broadcast port 11 of the reception port information 43 corresponding to the address “YY” in accordance with the contents of the address learning table unit 41, and is transferred to the 1 transfer network 200. And transferred to the B switch 2. At this time, the amount of frame data transferred to the broadcast port is added to “X byte”. Since no frame data is transferred to the 0-system transfer network 100, no frame data is transferred to the C switch 3 by flooding in the 0-system transfer network 100.

  FIG. 20 is a diagram showing a state after the amount of frame data transferred to the broadcast port reaches “Y byte” and the value of the transfer amount information 49 is changed from “X byte” to “Y byte”. is there. When the value of the transfer amount information 49 is “Y byte”, the frame data received from the A terminal 4 is transferred not only to the A1 system broadcast port 11 but also to the A0 system broadcast port 10. That is, the transfer operation to all broadcast ports is performed.

  In FIG. 21, the value of the transfer amount information 49 is changed from “Y byte” to “X byte” after transferring the frame data when the amount of the frame data transferred to the broadcast port is “Y byte”. It is a figure which shows a back state. When the value of the transfer flag information 44 is “X byte”, the frame data received from the A terminal 4 is transferred only to the A1 system broadcast port 11. That is, when the value of the transfer amount information 49 changes from “Y byte” to “X byte”, the frame data transfer unit 40 performs a transfer operation for transferring the frame data to the broadcast port stored in the reception port information 43. Return.

  Since the B switch 2 operates in the same manner as described above, when the failure of the transfer network is recovered, the frame data from the 0-system transfer network 100 recovered from the failure is received, and then the B switch 2 is addressed to the A switch 1 The frame data to be transmitted to is transmitted to the 0-system transport network 100 and the 1-system transport network 200.

  FIG. 22 is a diagram illustrating a state when the frame data transmitted from the B switch 2 is received. When the A switch 1 receives the frame data, it performs address learning, and in addition to the information in the address learning table unit 41, the address information 42 is “YY” and the reception port information 43 is “A0 system broadcast port 10”. , “A1 system broadcast port 11” and the transfer amount information 49 store a set of “X byte”. That is, it becomes the same state as the address learning table unit 41 when there is no failure in the transfer network.

  As described above, the frame data transfer system 500 enables the same transfer operation as the frame data transfer system 300 in the first embodiment. That is, when a failure occurs in the transfer network, it is possible to prevent the transmission quality of the frame data from being deteriorated, and when the transfer network is restored, highly reliable frame data can be transferred. The description of the operation when no failure has occurred in the transfer network is omitted.

It is a figure which shows the structure of the frame data transfer system to which the switch concerning Embodiment 1 of this invention is applied. It is a figure which shows an example of the address learning table part of the switch when the failure has not occurred in the frame data transfer system according to the first exemplary embodiment of the present invention. It is a figure which shows an example of the address learning table part of the switch when the failure has not occurred in the frame data transfer system according to the first exemplary embodiment of the present invention. It is a figure which shows an example of the address learning table part of the switch when the failure has not occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of the switch when the failure has not occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows the structure of the frame data transmission system to which the switch concerning Embodiment 2 of this invention is applied. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows the structure of the frame data transfer system to which the switch concerning Embodiment 3 of this invention is applied. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system. It is a figure which shows an example of the address learning table part of a switch when a failure has occurred in the frame data transfer system.

Explanation of symbols

1 A switch 2 B switch 3 C switch 4 A terminal 5 connected to the A switch 5 B terminal connected to the B switch 6 C terminal connected to the C switch 10 A0 system broadcast port 11 provided in the A switch 11 A1 system broadcast port 12 provided A terminal port 20 provided in the A switch B0 system broadcast port 21 provided in the B switch B1 system broadcast port 22 provided in the B switch B terminal port 30 provided in the B switch C0 system same equipment provided in the C switch Report port 31 C1 system broadcast port provided in C switch 32 C terminal port provided in C switch 40 Frame data transfer unit 41 for determining transfer destination of received frame Address learning table unit 42 Address information 43 Receive port information 44 Transfer flag information 45 Timer unit 46 for changing transfer flag information at predetermined intervals Table unit 47 A0 system broadcast port information 48 A1 system broadcast port information 49 Transfer amount information 100 indicating the amount of transferred frame data 100 system transfer network 200 1 system transfer network 300 Frame data transfer system 400 of the first embodiment Frame data transfer system 500 according to Embodiment 2 Frame data transfer system according to Embodiment 3 XX Address of A terminal YY Address of B terminal

Claims (4)

In a network system including a plurality of switch devices connected to a plurality of transfer networks forming a network,
Each of the switch devices is
A broadcast port for connecting each of the plurality of transfer networks;
A terminal port to which the terminal device is connected;
A frame data transfer unit for controlling the transfer destination of the frame data;
Address information for storing an address indicating a transmission source of frame data, port information for receiving frame data, and transferring frame data to all broadcast ports, or sending frame data to the broadcast port indicated in the reception port information An address learning table unit for storing transfer flag information representing either one of
A timer unit for changing the transfer flag information at predetermined intervals;
With
Control the operation of the frame data transfer unit by the operation of the timer unit,
Transfer frame data to all broadcast ports or broadcast ports indicated in the receive port information;
A network system characterized by The switch device is
A broadcast learning table unit for storing information representing a switch device that has performed broadcast transfer of frame data for each broadcast port that has received frame data transmitted from the network;
When the transfer flag information indicates that frame data is transferred to the broadcast port indicated by the reception port information, and there is a significant difference in the quantity of information stored in the broadcast learning table unit, the reception port information Forwarding frame data to the broadcast port indicated in
The network system according to claim 1. The switch device is
A broadcast learning table unit for storing information representing a switch device that has performed broadcast transfer of frame data for each broadcast port that has received frame data transmitted from the network;
When the transfer flag information indicates that frame data is transferred to the broadcast port indicated by the reception port information and there is no significant difference in the quantity of information stored in the broadcast learning table unit, Forwarding frame data to the reporting port,
The network system according to claim 1. In a network system including a plurality of switch devices connected to a plurality of transfer networks forming a network,
Each of the switch devices is
A broadcast port for connecting each of the plurality of transfer networks;
A terminal port to which the terminal device is connected;
A frame data transfer unit for controlling the transfer destination of the frame data;
Address information for storing an address indicating the transmission source of frame data, port information for receiving frame data, and transfer amount information for storing the amount of frame data transferred to the broadcast port by the frame data transfer unit are associated with each other. An address learning table section to store;
With
Controlling the operation of the frame data transfer unit according to the state of the transfer amount information, transferring frame data to all broadcast ports or broadcast ports indicated in the reception port information,
A network system characterized by

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